ES1301466U - SUPPORT SYSTEM FOR A TWO-WIRE SOLAR INSTALLATION (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Support system for a two-row solar installation, comprising: - two rows of solar trackers (1), each one comprising a turning axis (1.2) and a plurality of posts (1.4) fixed to the ground and configured to support each axis of rotation (1.2); and - a transmission system (2) connected to the two rotation axes (1.2) and configured to simultaneously transmit a rotation movement to the two rotation axes (1.2); characterized in that the transmission system (2) is connected to both rotation axes (1.2) by means of at least one transmission bar (5), connected at each end to each rotation axis (1.2); and because the transmission system (2) comprises at least one linear actuator (6) for the transmission of the turning movement, fixed by a first end (6.1) to the transmission bar (5) and by a second end to a pole (1.4). (Machine-translation by Google Translate, not legally binding)

Description

DESCRIPTION

SUPPORT SYSTEM FOR A TWO-WIRE SOLAR INSTALLATION

Technical sector

The present invention is related to the industry dedicated to solar trackers for photovoltaic panels, and more specifically to a support system that includes a transmission system configured to simultaneously transmit a rotation movement to two rows of solar trackers.

state of the art

At present, the production of electricity by means of photovoltaic panels by means of a photoelectric effect from the sunlight that falls on said photovoltaic panels is widely known.

The grouping of photovoltaic panels in the same structure of a solar installation, normally in rows, is also known. Said structure usually comprises at least one longitudinal axis in which each photovoltaic panel is fixed to the longitudinal axis by means of clamps, normally in such a way as to minimize the distance between photovoltaic panels, maximizing the number of photovoltaic panels per surface and increasing with it the generation of electricity per area used.

Likewise, it is known that said structures are solar trackers, that is to say that they are configured so that the longitudinal axes rotate around their longitudinal axis, so that sunlight falls at all times on the surface of the photovoltaic panels as perpendicular as possible. , increasing the generation of electricity.

In order to achieve efficient movement transmission and better adaptability to the different orographies in which solar trackers can be mounted, solutions are known in which motorized rotation modules are used to drive the rotation axes of the rows of solar trackers. , which are connected to other rows by means of transmission bars that transmit the movement of the motorized rotation module to a rotation axis of the adjacent solar tracker row. In this way, one achieves synchronization of the rotation of all the photovoltaic panels and a greater ease of adaptation to the terrain.

An example of this type of solution is found in the Utility Model document ES1271451, which deals with a solar tracker with a transmission bar that connects two rows of solar trackers, connected by cardan joints to the corresponding rotation modules of each row of solar tracker.

These types of solutions have the disadvantage that they cause the appearance of torsion forces that reduce the useful life of the solar installation. Likewise, this type of solution has a reduced mechanical transmission efficiency between rows of solar trackers.

Therefore, a support system for two-row solar installations is necessary that improves the mechanical transmission between rows of solar trackers with respect to what is known in the state of the art, as well as that reduces the intensity and/or number of forces of torsion, increasing the useful life of the support system.

Object of the invention

In order to meet this objective and solve the technical problems discussed so far, in addition to providing additional advantages that can be derived later, the present invention provides a support system for a two-wire solar installation, comprising:

- two rows of solar trackers, each one comprising a rotation axis and a plurality of posts fixed to the ground and configured to support each rotation axis; and - a transmission system connected to the two rotation axes and configured to simultaneously transmit a rotation movement to the two rotation axes;

where the transmission system is connected to both axes of rotation by at least one transmission bar, connected at each end to each axis of rotation; and where the transmission system comprises at least one linear actuator for the transmission of the turning movement, fixed by a first end to the transmission bar and by a second end to a post.

This configuration provides the solar installation with an improved mechanical transmission between rows of solar trackers, so that by simultaneously transmitting a movement of rotation to the axes of rotation synchronization of the movement of the axes of rotation is achieved.

This is achieved because the actuator is integrated and integral with said mechanical transmission: on the one hand, the linear actuator is fixed by the second end to at least one post, which is in turn fixed and anchored to the ground, so when the linear actuator extends or contracts, this movement is fully transmitted to the transmission rod attached to the first end of the linear actuator.

Preferably, the transmission system comprises two transmission bars, the linear actuator being pivotally fixed at its first end to the two transmission bars, thus improving load distribution by distributing the extension or contraction movement of the Linear actuator with two transmission bars, thus reducing the appearance of torsion forces.

In addition, the pivotal fixing of the linear actuator to the transmission bars allows angular movement of the linear actuator with respect to the transmission bars.

Preferably, the linear actuator is fixed to two posts that support the same axis of rotation by means of a support, thereby improving the fixing of the transmission system to the ground, improving the mechanical transmission of the linear actuator to the transmission bars.

Preferably, the support comprises a beam that includes at each end wings with slotted holes for fixing the beam to each respective post; and an intermediate support in which the second end of the linear actuator is pivotally fixed.

The fixing of the beam to each respective post by means of slotted holes allows personalized positioning during the assembly of the support, ensuring that, depending on the needs of the terrain, the beam (and therefore the transmission system) is parallel to the axis. rotation, reducing the generation of torsion forces and increasing the useful life of the support system.

Likewise, the pivotal fixing of the second end of the linear actuator to the intermediate support allows an angular movement of the linear actuator with respect to the support (and therefore with with respect to the posts).

Likewise, in combination with the pivoting fixing of the linear actuator to the transmission bars, it is achieved that the linear actuator can move angularly with respect to the support and the transmission bars, obtaining an improvement in mechanical transmission.

Preferably, the transmission bar is respectively connected to each axis of rotation by means of a transmission lever, which allows the transmission bar to be separated from the axis of rotation, which in turn allows a better distribution of forces. and facilitates the turning movement of the turning axes.

Preferably, each transmission lever is fixed at one end to its respective axis of rotation by means of a head configured to embrace the axis of rotation, and at the other end it is fixed in a pivotal manner to the transmission rod. In this way, with said head it is achieved that the fixing of the lever to the axis of rotation is more robust.

Likewise, with the pivoting fixing of the lever to the transmission bar, it allows the correct articulation of the transmission system, improving the mechanical transmission of the support system.

Description of the figures

Figure 1 shows a perspective view of a bifilar solar installation with the support system object of the invention.

Figure 2 shows a plan view of the transmission system.

Figure 3 shows an exploded view of the support.

Figure 4 shows a perspective view of the support of Figure 3.

Figure 5 shows a front view of the support of Figure 4.

Figure 6 shows a front view of the support where the axes of rotation are inclined with respect to horizontality.

Figure 7 shows an exploded view of the head.

Figure 8 shows a perspective view of the head of Figure 7.

Figure 9 shows a front view of the head of figure 8.

Figure 10 shows a frontal view of the head where the axes of rotation are inclined with respect to horizontality.

Figure 11 shows an exploded view of the fixing of the transmission bars to the head.

Figure 12 shows an isometric view of the transmission bars attached to the heads.

Figure 13 shows an exploded view of the fixing of the actuator to the support and to the transmission bars.

Figure 14 shows an isometric view of the actuator once fixed to the support and to the transmission bars.

Figure 15 shows a side view of the support system for two rows of solar trackers.

Figure 16 shows a side view of the support system of Figure 15 where the linear actuator is extended.

Figure 17 shows a side view of the support system of figure 15 where the linear actuator is retracted.

Detailed description of the invention

The present invention refers to a support system for a two-wire solar installation, that is, it comprises two lines of solar trackers (1). As can be verified in figure 1, each line of solar tracker (1) comprises a plurality of photovoltaic panels (1.1) fixed to a rotation axis (1.2) by means of clamps (1.3).

Likewise, each solar tracker line (1) comprises a plurality of vertical posts (1.4) fixed to the ground and configured to support each rotation axis (1.2) by means of rotation modules (1.5) located at the end of the posts. (1.4) that are further from the ground.

In order to facilitate the transport of the rotation axes (1.2), it is not ruled out that the rotation axes (1.2) comprise several sub-axes, which are fixed longitudinally during the assembly of the rotation axis (1.2).

Likewise, the support system comprises a transmission system (2) connected to each axis of rotation (1.2) configured to simultaneously transmit a movement of rotation to the two axis of rotation (1.2).

In a preferred embodiment, and as can be seen in figures 1 and 2, the transmission system (2) comprises a transmission bar (5), respectively connected at each end to a different axis of rotation (1.2). by means of transmission levers (4).

Likewise, the transmission system (2) comprises a linear actuator (6), fixed by a first end (6.1) to the transmission bars (5) and by a second end to two posts (1.4) by means of a support ( 3).

As can be seen in figures 3 and 4, the support (3) comprises a beam (3.1), preferably with a square section. To avoid the accumulation of dirt inside the beam (3.1), both ends of the beam (3.1) are covered with covers (3.1.1).

The support (3) comprises at each end of the beam (3.1) some wings (3.2), preferably the support (3) comprises at each end of the beam (3.1) two L-shaped wings (3.2), where each wing (3.2) comprises a first surface that extends from one face of the beam (3.1) which, once mounted on the support system, is in contact with the posts (1.4), and where each wing (3.2) comprises a second surface perpendicular to the first surface as a reinforcing rib.

Preferably, the posts (1.4) are fixed vertically to the ground, having a "C"-shaped section, and comprising slotted holes (3.4) at one end (vertically arranged for the example shown) for fixing the post. support (3).

Likewise, the first surface of the wings (3.2) includes slotted holes (3.4) whose longitudinal dimension extends transversally to the slotted holes (3.4) of the posts (1.4) (horizontally for the example shown) in relation to the slotted holes. (3.4) of the posts (1.4) for fixing the support (3) to the posts (1.4) by means of fixing means (7).

Fixing means (7) are understood to be any part that serves to fix two or more elements, for example, the fixing means (7) can comprise screws, nuts, washers, etc.

To improve the fixing of the support (3) to the post (1.4), the use of a plate (3.2.1) with holes for the passage of the fixing means (7) is proposed. This plate (3.2.1) is located in The inside of the post (1.4), preferably the sheet (3.2.1), has an extension that would allow the slotted holes (3.4) of the post (1.4) corresponding to the fitting of the two wings (3.2) of the end of the support to be covered at the same time. (3).

For fixing the linear actuator (6) to the support (3), the support (3) comprises an intermediate support (3.3), preferably located between the posts (1.4) to which the support (3) is fixed, and more preferably at an equidistant distance from each post (1.4).

The intermediate support (3.3) comprises an upper section (3.3.1), configured for fixing with the linear actuator (6), and a lower section (3.3.2), configured for fixing the intermediate support (3.3) to the beam (3.1).

"Upper" is understood as the part that, once the support system is assembled, is furthest from the ground and therefore closest to the axis of rotation (1.2).

The upper section (3.3.1) has an "Omega" shaped section with a size capable of containing the beam (3.1), so that, during assembly, the upper section (3.3.1) together with the lower section ( 3.3.2) embrace the beam (3.1).

Likewise, the upper section (3.3.1) comprises at least two lateral plates, where each lateral plate includes a hole for the passage of a pivot axis (8) that is supported between both lateral plates, and to which it is fixed in a fixed manner. pivoting one end (6.2) of the linear actuator (6).

In addition, the upper section (3.3.1) includes lateral projections of the "Omega"-shaped section, holes for fixing the upper section (3.3.1) with the lower section (3.3.2) by means of of fixing means (7).

Preferably, the lower section (3.3.2) has a "C"-shaped section, and includes holes that coincide with the holes in the lateral projections of the upper section (3.3.1) for fixing the lower section (3.3 .2) to the upper section (3.3.1).

This allows, during the assembly of the support (3), the intermediate support (3.3) to embrace the beam (3.1) in a sliding manner, allowing the operator to move the intermediate support (3.3) along the beam (3.1) until its mounting position, at which time the upper section (3.3.1) and the lower section (3.3.2) are fixed, blocking the movement of the intermediate support (3.3). It is also contemplated that the intermediate support (3.3) is fixed by welding to the beam (3.1).

Figure 5 shows an example of mounting a row of solar trackers (1) where the axis of rotation (1.2) is horizontal (for example, if the ground is flat). As can be seen, the beam (3.1) of the support (3) is preferably parallel to the axis of rotation (1.2) once assembled in a row of solar tracker (1).

Likewise, in figure 6 the support (3) can be seen once assembled in a row of solar tracker (1) with an inclined axis of rotation (1.2) (for example, in the event that the ground is inclined, with slopes, etc.). As can be seen, the beam (3.1) of the support (3) is preferably parallel to the axis of rotation (1.2) once assembled in a row of solar tracker (1).

Thanks to the slotted holes (3.4) of the wings (3.2) of the support (3) and of the posts (1.4) it is facilitated that the beam (3.1) of the support (3) remains parallel to the axis of rotation (1.2) during the Mounting of the support system.

When the beam (3.1) of the support (3) is parallel to the axis of rotation (1.2), the mechanical transmission of the transmission system (2) is improved because in this way the appearance of torsion forces is avoided, which in turn, they would decrease the useful life of the support system.

As can be seen in figures 7 and 8, the transmission lever (4) comprises a head (4.1) and a clamp (4.2), configured to embrace the axis of rotation (1.2).

Likewise, the transmission lever (4) comprises an intermediate section (4.3) in the shape of an inverted T configured to allow pivoting fixing of the transmission bars (5).

This allows the transmission bar (5) to be moved away from the axis of rotation (1.2), which in turn allows a better distribution of forces.

The head (4.1) has an "Omega"-shaped section with a size capable of containing the axis of rotation (1.2), and includes a mooring (4.2) so that, during the assembly of the support system, the head ( 4.1) together with the clamp (4.2) embrace the axis of rotation (1.2).

In addition, the head (4.1) includes lateral projections of the "Omega"-shaped section with holes for fixing the head (4.1) with the mooring (4.2) by means of fixing means (7).

Likewise, the mooring (4.2) has a "C"-shaped section, and includes holes on the underside for fixing the mooring (4.2) to the head (4.1).

This allows, during the assembly of the transmission lever (4), the combination of head (4.1) and clamp (4.2) to embrace the rotation axis (1.2) in a sliding manner, allowing the operator to move the transmission lever (4 ) along the axis of rotation (1.2) until its mounting position, at which time the head (4.1) and the clamp (4.2) are fixed, blocking the movement of the transmission lever (4) with respect to the axis of rotation. turn (1.2).

With this it is achieved that, when the transmission lever (4) is actuated (for example, the transmission bars (5) push or pull the transmission lever (4)), the transmission lever transmission (4) rotates around the axis of rotation (1.2), transmitting the movement of rotation to the axis of rotation (1.2).

The intermediate section (4.3) comprises a lower part of fixing elements (4.3.1) configured to fix the transmission bars (5), preferably the intermediate section (4.3) comprises two fixing elements (4.3.1) per each transmission bar (5) to be fixed to the transmission lever (4).

The "lower" part of the intermediate section (4.3) is understood as the part of the intermediate section (4.3) that, once the support system is assembled, is furthest from the axis of rotation (1.2) and therefore the closer to the ground.

In this preferred embodiment, the intermediate section (4.3) includes four fixing elements (4.3.1), which have a "C"-shaped section, and include holes in their central part for the passage of a pivot axis (8), for pivoting fixing of the transmission bars (5).

Figure 9 shows an example of mounting a row of solar trackers (1) where the axis of rotation (1.2) is horizontal (for example, if the ground is flat). As can be seen, both the central area of the intermediate section (4.3) and the fixing elements (4.3.1) of the transmission lever (4) are preferably mounted perpendicular to the axis of rotation (1.2) once mounted on a row of solar tracker (1).

Likewise, in figure 10 the transmission lever (4) can be seen once assembled in a row of solar tracker (1) with an axis of rotation (1.2) inclined with respect to horizontality, (for example, because it is in a sloping floor, with unevenness, etc.). Due to how the transmission lever (4) is fixed to the axis of rotation (1.2), when the axis of rotation (1.2) is inclined with respect to horizontality, both the central zone of the intermediate section (4.3) and the fixing elements (4.3.1) of the transmission lever (4) are perpendicular to the axis of rotation (1.2).

With this, an improvement in the useful life of the support system is achieved since the effect of torsion forces is reduced.

Likewise, each pair of fixing elements (4.3.1) is located at one end of the intermediate section (4.3) and at an equidistant distance from the central area of the intermediate section (4.3), reducing the appearance of torsion forces that would decrease the useful life of the support system.

As can be seen in figures 11 and 12, the transmission bars (5) have holes at their ends for the passage of the pivot axis (8) of the transmission lever (4) for pivoting fixing of the bars. transmission (5) with the transmission lever (4).

Likewise, the transmission bars (5) comprise a through hole for the passage of a pivot axis (8) for pivoting fixing of the linear actuator (6) with the transmission bars (5), preferably the through hole is located an equidistant distance from the ends of the transmission bars (5).

In figures 13 and 14, it can be seen how the linear actuator (6) is pivotally fixed by a first end (6.1) to the transmission bars (5), by means of the pivot axis (8), and by a second end (6.2) is pivotally fixed to the support (3).

Preferably, the linear actuator (6) is located between the transmission bars (5), more preferably at an equidistant distance from the transmission bars (5), which reduces the generation of torsion forces, increasing the useful life of support system.

Preferably, the linear actuator (6) comprises a motor (6.3) at the first end (6.1), either longitudinally or parallel to the linear actuator (6), to generate the expansion or retraction of the linear actuator (6).

As can be seen in figures 15 to 17, the expansion (figure 16) or retraction (figure 17) of the linear actuator (6) causes the movement of the transmission bars (5) so that the transmission bars (5 ) push the transmission lever (4) of one row of the sun tracker (1) and at the same time pull the transmission lever (4) of the other row of the sun tracker (1), causing the transmission of the rotation movement to the axis of rotation (1.2) of each row of solar tracker (1).

Claims (6)

1. - Support system for a two-wire solar installation, comprising: - two rows of solar trackers (1), each one comprising a rotation axis (1.2) and a plurality of posts (1.4) fixed to the ground and configured to support each rotation axis (1.2); and - a transmission system (2) connected to the two rotation axes (1.2) and configured to simultaneously transmit a rotation movement to the two rotation axes (1.2); characterized in that the transmission system (2) is connected to both rotation axes (1.2) by means of at least one transmission bar (5), connected at each end to each rotation axis (1.2); and because the transmission system (2) comprises at least one linear actuator (6) for the transmission of the turning movement, fixed by a first end (6.1) to the transmission bar (5) and by a second end to a pole (1.4). 2. - Support system, according to the preceding claim, where the transmission system (2) comprises two transmission bars (5) with the linear actuator (6) pivotally fixed by its first end (6.1) to the two transmission bars (5). 3. - Support system, according to any one of the preceding claims, where the linear actuator (6) is fixed to two posts (1.4) that support the same axis of rotation (1.2) by means of a support (3 ). 4. - Support system, according to the preceding claim, wherein the support (3) comprises a beam (3.1) comprising at each end wings (3.2) with slotted holes (3.4) for fixing the beam ( 3.1) to each respective post (1.4); and an intermediate support (3.3) in which the second end (6.2) of the linear actuator (6) is pivotally fixed. 5. - Support system, according to any one of the preceding claims, wherein the transmission bar (5) is respectively connected to each axis of rotation (1.2) by means of a transmission lever (4). 6. - Support system, according to the preceding claim, where each transmission lever (4) is fixed at one end to its respective axis of rotation (1.2) by means of a head (4.1) configured to embrace the axis of turn (1.2), and at the other end it is fixed pivotingly to the transmission bar (5).